Method and system of laser-driven impact acceleration

Abstract

A system and a method for laser-driven propulsion, comprising transferring momentum to a projectile through a low-density material at laser fluences below plasma ablation threshold, the method comprising providing a metal layer having a first surface and a second opposite surface; providing a low density layer having a first surface and a second opposite surface; positioning the low density layer with the first surface thereof in direct contact with the second surface of the metal layer; positioning a projectile on the second surface of the low density layer; and heating the metal layer with laser pulses to temperatures below the liquefaction and ionization thresholds of the metal.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a National Entry Application of PCT application no PCT/CA2017/050991 filed on Aug. 22, 2017 and published in English under publication number WO 2018/094504 under PCT Article 21(2), which itself claims benefit of U.S. provisional application Ser. No. 62/425,924, filed on Nov. 23, 2016. All documents above are incorporated herein in their entirety by reference.

FIELD OF THE INVENTION

The present invention relates to laser-driven propulsion. More specifically, the present invention is concerned with a method and a system for laser-driven propulsion of projectiles.

BACKGROUND OF THE INVENTION

Accelerated masses of cold and hot solids are used in various applications related to material science, including surface coating, blasting, hardening and impact initiation of detonation for instance.

In material deposition processes, small particles are accelerated to high velocities and subsequently impacted on a surface to produce a coating or some other desired process. In a conventional method, a powder of particles is accelerated by injection in a high velocity gas stream [1, 2]. Lasers have been combined to particle transportation in gas flow to increase the particle velocity [3].

Direct laser-driven propulsion of projectiles, including small particles, has been demonstrated and studied with lasers generating pulses from femtosecond duration with high repetition rate to nanosecond duration with large energy per pulse. High-speed ballistic propulsion of a projectile by a laser is based on plasma generation, depending of the laser fluence on the projectile, and subsequent recoil force or ablation propulsion.

Methods have also been developed, associated to nanosecond laser systems, to increase the coupling between the laser and an accelerated projectile by using layered target confining the vaporized surface or the plasma at the interface between a transparent layer such as water or glass for example and an absorbing back-plate [4]. In these methods, the confinement of the heated area or plasma at the interface maintains the pressure during a time that is longer than the laser pulse duration, increasing the momentum transferred to the target [5, 6, 7]. Momentum transfer larger than 1 Mbar.ns can be produced when the laser fluence at the interface is larger than the ablation threshold, which is around 5 J/cm² for a nanosecond pulse. Below the ablation threshold, the heated surface still transfers momentum but the effect rapidly decreases when the fluence is decreased. Thus, most practical applications of this method are based on the plasma generation with fluence well above the ablation threshold. This requires the use of large energy laser systems, which have limited repetition rates.

In the present state of the art, a laser-driven propulsion system is based on the generation of plasma to produce efficient ablative acceleration of solid at high velocities in air or in a high vacuum interaction chamber [8]. The system typically comprises a high intensity laser system, either a Ti:Sapphire laser [9] or a CO₂ laser [7] or Nb based system [6,7,10,11] with high energy, delivering pulse duration in the femtosecond to nanosecond range, focused by focusing optics on a solid projectile plate positioned at some distance from the focusing optics along the focusing optics axis and, eventually, an impact target positioned at some distance of the projectile.

The system usually requires a surface intensity higher than around 10⁹ W/cm² and a fluence above a threshold of around 5 J/cm² (ablation threshold for metal) for nanosecond pulses. Confined plasma is usually generated at the glass/projectile interface in order to generate high ablation pressure and subsequent momentum transfer. In some experiments, a multilayer target was used with black paint or glue at the interface to increase laser absorption and increase plasma effect [5]. The layer limits the use of shorter pulses due to the lower damage threshold and due to the presence of non-linear effects at shorter pulse duration [12, 13].

When the projectile mass is large compared to the ablated mass, the target velocity v is measured to be proportional to a coupling coefficient C_m and to the laser energy E_L and inversely proportional to the target mass m, as v=C_mE_L/m.

Maximum coupling coefficient C_m around 10⁻³N/W has been achieved in confined plasma mode with nanosecond pulses. The transferred momentum saturates when the fluence is increased above 40 J/cm² due to the breakdown of the transparent window when the laser intensity is too high [7].

This method accelerating thin film of material by the pressure generated by a laser-produced plasma was used for bonding two dissimilar materials [14].

Low coupling coefficient in the 10⁻⁵N/W range has been measured in air and no confinement effects, with laser pulses in the femtosecond-picosecond range [15].

There is still a need in the art for a method and system of laser-driven impact acceleration.

SUMMARY OF THE INVENTION

More specifically, in accordance with the present invention, there is provided a method for accelerating a projectile, comprising providing a metal layer having a first surface and a second opposite surface; providing a low density layer having a first surface and a second opposite surface; positioning the low density layer with the first surface thereof in direct contact with the second surface of the metal layer; positioning a projectile on the second surface of the low density layer; and heating the metal layer with laser pulses to temperatures below the liquefaction and ionization thresholds of the metal.

There is further provided a method for laser-driven propulsion, comprising transferring momentum to a projectile through a low-density material at laser fluences below plasma ablation threshold.

There is further provided a system, comprising a laser source and a target comprising an accelerating part and a projectile part, the accelerating part comprising a metal layer and a low density layer pressed against the metal layer; wherein the laser source is selected to emit pulse beams directed to the metal layer at a fluence below the plasma ablation threshold of the material of the metal layer.

Other objects, advantages and features of the present invention will become more apparent upon reading of the following non-restrictive description of specific embodiments thereof, given by way of example only with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the appended drawings:

FIG. 1 is a schematic view of a system according to an embodiment of an aspect of the present invention;

FIG. 2 is a schematic view of a target according to an embodiment of an aspect of the present invention;

FIG. 3 is a schematic view of a target according to an embodiment of an aspect of the present invention;

FIG. 4A schematically shows a pressure wave generated in a target according to an embodiment of an aspect of the present invention;

FIG. 4B schematically shows a hot cavity created in the target by the pressure wave of FIG. 4A;

FIG. 5 shows the measured momentum per unit surface (Mbar.ns) transferred to a solid aluminum target as a function of the aluminium layer thickness for a laser fluence (1.7 J/cm²) below the ablation threshold;

FIG. 6 shows the measured momentum per unit surface (Mbar.ns) transferred to a solid density aluminum cylinder in a confined mode as a function of the laser fluence (Al layer thickness 28 μm);

FIG. 7 shows the measured momentum per unit surface (Mbar.ns) transferred to a pre-compacted aluminum disc in a confined mode as a function of the laser fluence (Al layer thickness 20 μm), the zone grey representing a trend obtained with solid targets (FIG. 5);

FIG. 8 presents the compaction effect in the pre-compacted powder due to the shock propagation at fluence of 4.5 J/cm² with a Gaussian pulse; the radial compaction profile is obtained with a 80% pre-compacted powder and the aluminum layer thickness is 20 μm;

FIG. 9 shows the effect of the pre-compaction density on the compaction maximum depth (fluence of 4.5 J/cm² and aluminum layer thickness 20 μm); and

FIG. 10 shows the cavity depth, for a 80% pre-compacted powder, as a function of the laser fluence (20 μm aluminum layer); the dotted line is to guide the eye; the data at 1 J/cm² is at the limit of resolution (1 μm) of the depth measurement method.

DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

The present invention is illustrated in further details by the following non-limiting examples.

A system according to an embodiment of an aspect of the present invention as illustrated in FIG. 1 for example comprises a laser 1, optics comprising a mirror 2, a beam shaper 3 and a focusing lens 4, and a target 5.

The laser 1 is selected to emit picosecond to nanosecond pulse beams, i. e. of a duration in a range between about 10 μs and about 50 ns. In the examples illustrated in FIGS. 2-5, the beam shaper 3 is used to generate a focal plane flat top laser beam profile. Other profiles may be contemplated (see FIG. 7).

The target 5 comprises a layer of porous, i.e. low density, material such as pre-compacted powder. In embodiments illustrated in FIGS. 2 and 3, the target comprises a multilayer accelerating part and a projectile 50 to be accelerated. The accelerating part comprises a transparent layer 20, a metal layer 30 in close contact on the rear side of the transparent layer 20, and a layer 40 of pre-compacted powder in close contact with the rear side of the thin metal layer 30. The transparent layer 20 has a thickness in a range between about 500 μm and about 1 cm, the metal layer 30 has a thickness in a range between about 1 μm and about 50 μm, and the layer of pre-compacted powder 40 has a thickness in a range between about 10 μm and about 100 μm.

The transparent layer 20 is found to confines the laser effect, i.e. absorption, heating, plasma formation for examples, at the surface of the layer 30, while restraining its thermal expansion, thereby allowing isochoric heating of the front surface of the metal layer 30 to high electron temperature. The transparent layer 20 may be Plexiglas, glass such as silicate SiO₂, borosilicate glass BK7 or any other type of high optical quality glasses, for a laser wavelength of 1 μm or less and NaCl for a laser wavelength of 10 μm for example.

As shown in an embodiment illustrated for example in FIG. 3, a projectile support 60 may be used in case of a projectile 50 of a small size, i.e. of a diameter less than a few hundreds of μm.

In order to ensure a tight contact between the different layers forming the accelerating part of the target 5, a thin layer of liquid such as water for example, i.e. 5 μm thick for example, may be placed at the interfaces between the layers. The projectile 50 is thus pressed against the porous layer 40.

The laser beam (L) propagates through the transparent layer 20 and interacts with the front surface of the metal layer 30 at the interface between the transparent layer 20 and the metal layer 30 at a fluence in a range between about 1 and about 3 J/cm², i. e. below the plasma ablation threshold of the material of the metal layer 30. For example, in the literature, values for the single pulse ablation (plasma) threshold of aluminum are comprised in the range between 4 J/cm² and 5 J/cm² for a laser pulse of a wavelength of 1 μm and a pulse duration of a few nanoseconds, i.e. typically between about 1 ns and about 5 ns.

FIGS. 4A and 4B illustrate schematically a sequence of events and effects occurring according to an embodiment of an aspect of the present invention. Below the plasma ablation threshold of the metal layer 30, a large fraction of the laser energy is absorbed at the interface between the transparent layer 20 and the metal layer 30 producing a rapid and isochoric heating of front surface of the metal layer 30 to high electron temperature. Equilibrium is achieved between the electron and ion temperatures inside the metal layer 30 through electron to ion transfer on a picosecond time scale. The thickness of the metal layer 30 is selected to be about two times the conduction length at the end of the laser pulse (L) so that the heat remains localized within the metal layer 30 during the laser pulse (L). As a result, a pressure wave (F) is generated through a thermal process in the metal layer 30 (see stippled lines in FIG. 4A), which propagates and compacts the material of the pre-compacted powder layer 40 (see stippled lines in FIG. 4B).

The pressure wave (F), acting as a piston in the pre-compacted powder layer 40, compacts the powder grains of the pre-compacted powder layer 40 forward thus creating a hot cavity (C) (see FIG. 4B). The cavity (C) subsequently expands after the laser pulse through adiabatic cooling and this volume change produces a net momentum well above the initial momentum generated by the laser-matter interaction process at the interface between the transparent layer 20 and the metal layer 30, and which ejects the projectile 50 (see FIG. 4B). No plasma is required and the projectile 50 is not damaged.

Experimental results are presented below. The various parameters in these experiments have been chosen for practical reasons.

In an experiment related to the optimization of the thickness of the metal layer 30, a Nd:YAG laser system (Propulse™) delivering at a wavelength of 0.53 μm and pulse duration of 6 ns, with a repetition rate of 10 Hz, was focused by a lens of focal length 50 cm on a target at normal incidence in air. The laser beam diameter was 1 cm and the intensity distribution in the target plane was flat top. The transparent layer 20 was a borosilicate glass BK7. The metal layer 30 was a thin solid aluminum layer of a thickness varying in the range between about 0 and about 50 μm. The projectile 50 was a solid pure cylindrical aluminum disc of a surface of 1 cm² and a thickness of 1 mm. The momentum transferred to the disc was deduced from the measurement of the ballistic trajectory of the accelerated disc.

FIG. 5 shows the measured momentum per unit surface (Mbar.ns) transferred to the projectile 50 as a function of the thickness of the aluminum layer 30 and for a laser fluence of 1.7 J/cm², corresponding to a laser intensity of 0.25 GW/cm². An optimized momentum transfer is observed for a thickness of the aluminum layer 30 in the range between about 20 and about 30 μm. It can be calculated [16] that, in these conditions, the absorption is 50% and the conduction length is 7 μm. Below a thickness of the aluminum layer 30 of 10 μm, a low momentum transfer is observed, which could be due to an increase of the temperature of the aluminum layer 30 above fusion threshold and eventually vaporization threshold, inducing a dramatic decrease of absorption and of the related pressure.

FIG. 6 shows the measured momentum per unit surface (Mbar.ns) transferred to a solid density aluminum cylinder as the projectile 50, in a confined mode, with an optimized thickness of the thin aluminum layer 30 of 28 μm, as a function of the laser fluence. A low fluence threshold is observed at 0.6 J/cm², corresponding to a laser intensity of 0.09 GW/cm². The momentum increases as the fluence increases as expected and in agreement with published data. Momentum around 2 Mbar.ns measured at 10 J/cm² is consistent with previous published results obtained with solids [5-7] in the plasma regime, indicating that the plasma ablation effect dominates over the thermal generation of stress wave at very high fluence.

A second set of experiments related to the use of a pre-compacted powder layer 40 to increase the momentum transferred at low fluence. A Nd:YAG laser system (Surelyte™) delivering 330 mJ at the wavelength of 1.06 μm and pulse duration of 10 ns, with a repetition rate of 10 Hz, is focused by a lens (f=50 mm) on a target 50 at normal incidence. The laser beam intensity distribution in the target plane was Gaussian. The transparent layer 20 was a borosilicate glass BK7 layer. The metal layer 30 was a 20 μm thin aluminum layer (solid density). In a first experiment, the pre-compacted powder layer 40 and the projectile 50 were a same layer, i.e. the projectile was a cylindrical disc of pre-compacted aluminum powder, having a surface of 1 cm² and a thickness of 1 mm, with a 80% pre-compaction rate achieved with a mechanic press and pressure around 1 GPa.

The focal spot diameter was varied at constant laser energy to adjust the laser fluence on the target between 1 J/cm² and 10 J/cm². It should be noted that, for practical reasons, in these experiments, the diameter of the projectile 50 was larger than the laser focal spot diameter. The momentum transferred to the projectile 50 was deduced from the measurement of the ballistic trajectory of the accelerated projectile 50. FIG. 7 shows the measured momentum per unit surface (Mbar.ns) transferred to the pre-compacted powder projectile 50 as a function of the laser fluence (0.5 J/cm²-10 J/cm²). With the pre-compacted powder projectile, a maximum momentum transfer (0.8 Mbar.ns) is observed for fluences between about 2 J/cm² and about 3 J/cm², corresponding to intensity between about 1×10⁸ W/cm² and about 2×10⁸ W/cm² (1-2 GW/cm²). A saturation effect is observed for the momentum transferred to the pre-compacted powder projectile at high fluence (9.5 J/cm²) and is attributed to a competition between the thermal effect of the cavity (C) discussed hereinabove and the plasma generation. The momentum drastically decreases for fluence below 1 J/cm² to the level obtained with a solid projectile and this is attributed to a decrease of the cavity effect, the size of the cavity (C) being too small, due to a pressure too low to move the powder grains at these fluences and laser wavelength.

Different types of transparent layer 20, such as Plexiglas, Pyrex, glass and BK7 for example, were tested and the results were independent of the nature of this transparent confinement layer. Similar results were also been obtained at 2 J/cm² with a pre-compacted powder layer 40 having a 1 cm² surface, a 100 μm thickness and a 80% pre-compaction decoupled from the projectile 50 as a cylindrical disc of 80% pre-compacted aluminum powder having a surface of 1 cm² and a thickness of 1 mm, positioned behind the pre-compacted layer 40.

The energy transferred to the system composed of the pre-compacted powder layer 40 and the projectile 50 is divided into work done on the material thereof and kinetic energy. In a low mass density material, this results in a compaction of a fraction of the pre-compacted layer 40 and in acceleration of the total mass of the projectile 50. The shock wave passing through the pre-compacted layer 40 densifies the powder, the powder grains being pushed forward of the wave under the pressure thereby creating a cavity. FIG. 8 illustrates this effect by showing the shape of the cavity (C) produced in one laser shot and with a fluence of 4.5 J/cm², at the surface of a pre-compacted projectile, in case of an aluminum layer 30 of a thickness of 20 μm. The radial cavity profile observed is related to the radial laser intensity profile, which was Gaussian in this case, and thus to the radial pressure profile, in the focusing plane. The maximum cavity depth is a function of the laser fluence and of the pre-compaction ratio of the powder in which the cavity effect is created. The cavity is larger for lower pre-compaction density of the powder as shown in FIG. 9 indicating that the thickness of the porous layer 40 needs to be less than 100 μm and can be adjusted as a function of the laser parameters. In addition the cavity depth increases with the laser fluence as indicated by the profile observed in FIG. 8 and as shown in FIG. 10. Motion of the powder grains is triggered above a pressure threshold, which is about 1 J/cm² with the present parameters. This explains why the measured momentum in FIG. 7 drops rapidly when the fluence is below 1 J/cm².

The acceleration performance of the method, and the operating fluence window, can be optimized by adjusting the parameters, in particular by controlling the pre-compaction density or porosity of the intermediate porous layer 40 in which the cavity effect is created, by selecting the material for the metallic layer 30, such as aluminum, copper, iron stainless steel, and of the porous layer 40 in order to increase the pressure in the porous layer 40 by shock impedance matching increasing the cavity depth, by increasing the pulse duration in order to increase the heating in the metallic layer 30 and the compaction piston effect, by increasing the laser wavelength and using, as an example, a NaCl transparent layer 20 in conjunction with a CO₂ laser pulse at 10 μm wavelength in order to modify the ablation parameters, and by controlling the laser intensity profile to achieve a flat top profile. As an example, a pre-compacted aluminum disc with 80% of compaction having a diameter of 2 mm and a thickness of 300 μm can be accelerated at a velocity larger than 100 m/s with a fluence of 2 J/cm², 10 ns pulses, 1 μm wavelength, 25 μm aluminum layer 30 and a 100 μm thick pre-compacted aluminum layer 40 with 80% of compaction.

There is thus provided a method comprising heating a metal layer with laser pulses below the liquefaction and ionization thresholds of the metal, resulting in the creation of a hot cavity in a low density layer in direct contact with the metal layer, the cavity expanding and generating a high pressure wave within the low density layer, this high pressure wave in turn accelerating a low mass density projectile, i. e. in a range between about 1 g/cm³ and about 5 g/cm³, in direct contact with the low density layer to high velocities, depending of the weight of the projectile, i.e. of up to about 100 m/s for a projectile of a weight of 2 mg for example, this accelerated projectile being thus usable as an impact projectile on a given surface.

The low mass density projectile may be made of compacted powders, low porosity material, array of micro-dots, or foams for example. It may be fabricated by direct 3D printing on a transparent membrane or by surface patterning with femtosecond lasers or array of many dots disposed in 3D with a well-controlled porosity for example.

The method can be used to optically accelerate and utilize projectiles having a non-uniform composition, which can be obtained by mixing and pre-compacting powders of different low atomic numbers materials.

The method can also be used to accelerate ultra-small masses, i.e. projectiles of a volume in a range between about 1 μm³ and about 1000 μm³, of low atomic number, i.e. in the range between about 1 and about 10, material to very high velocities without ionization or ablation.

A potential application is the use of a cold ultra-small mass projectile inside an optical system, which could focus a very high peak power. i.e. in a range between about 1 PW and about 10 PW, femtosecond laser system at very high intensity, i. e. an intensity of at least 10²³ W/cm², so that the projectile arrives with a controlled timing at the focal spot of the optics to be used as a localized target, giving the possibility to achieve laser-matter interaction at ultra-high intensity, i.e. intensity of at least 10²³ W/cm², without requiring any mechanical target support, with controlled temporal synchronization between the arrival of the target and the arrival of the high peak power laser pulse, and with controlled localization of the ultra-high intensity laser-matter interaction and processes.

The method can also be applied with any kind of laser repetition rate used with any kind of focusing optics, including high numerical aperture (HNA) focusing geometry.

The method extends the range of applicability of the laser-driven method to a non-plasma acceleration regime obtained with lower laser fluence, which is particularly convenient for the use of lower energy laser systems with higher average power or for acceleration without damages of low mass density and low thermal conductivity materials, either compacted powders, low porosity material, array of micro-dots,

There is thus provided a method and a system comprising isochoric heating at the interface between a transparent layer and a first metal layer, generating a shock wave which builds up and propagates through this first metal layer. A second layer, behind the metal layer, is a pre-compacted powder layer, which compacts and deforms under action of the shock wave. This deformation creates a hot cavity between the first metal layer and the pre-compacted powder layer, which subsequently cools and expands adiabatically. This adiabatic cooling produces momentum enhancement, compared to a situation without a pre-compacted powder layer, and accelerates a projectile positioned behind the pre-compacted powder layer.

The scope of the claims should not be limited by the embodiments set forth in the examples, but should be given the broadest interpretation consistent with the description as a whole.

REFERENCES

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Claims

1. A method for accelerating a projectile, comprising:

providing a metal layer having a first surface and a second opposite surface;

providing a porous layer of pre-compacted powder, the porous layer having a first surface and a second opposite surface;

positioning the porous layer with the first surface thereof in direct contact with the second surface of the metal layer;

positioning a projectile on the second surface of the layer; and

irradiating the first surface of the metal layer with laser pulses of a fluence between 1 and 3 J/cm² to temperatures below the liquefaction and ionization thresholds of the metal, thereby generating a pressure wave in the metal layer;

whereby the pressure wave propagates and compacts the pre-compacted powder of the porous layer, thus creating a cavity, and the cavity transfers momentum to the projectile.

2. The method of claim 1, comprising selecting the metal layer with a thickness in a range between 1 μm and 50 μm and a thickness of the layer in a range between 10 μm and 100 μm.

3. The method of claim 1, comprising providing a transparent layer on the first surface of the metal layer.

4. The method of claim 1, comprising providing a transparent layer of a thickness in a range between 500 μm and 1 cm on the first surface of the metal layer, and selecting the metal layer with a thickness in a range between 1 μm and 50 μm and a thickness of the layer in a range between 10 μm and 100 μm.

5. The method of claim 1, comprising selecting a pre-compaction density of the pre-compacted powder.

6. The method of claim 1, comprising selecting the materials of the metal layer and of the porous layer for shock impedance matching.

7. The method of claim 1, wherein the layer is part of the projectile.

8. The method of claim 1, wherein the-projectile is an array of micro-dots.

9. The method of claim 1, wherein the projectile is a foam.

10. A method for laser-driven propulsion of a projectile, comprising creating a hot cavity in a porous layer of pre-compacted powder positioned with a first surface thereof in direct contact with a first surface of a metal layer, the projectile being positioned on a second surface of the porous layer, by irradiating a second surface of the metal layer with laser pulses of a fluence in a range between 1 and 3 J/cm² to temperatures below the liquefaction and ionization thresholds of the metal; the cavity expanding and generating a pressure wave within the porous layer, thereby transferring momentum to the projectile.